/*
 * Copyright (c) 2000-2009 Apple Inc. All rights reserved.
 *
 * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
 * 
 * This file contains Original Code and/or Modifications of Original Code
 * as defined in and that are subject to the Apple Public Source License
 * Version 2.0 (the 'License'). You may not use this file except in
 * compliance with the License. The rights granted to you under the License
 * may not be used to create, or enable the creation or redistribution of,
 * unlawful or unlicensed copies of an Apple operating system, or to
 * circumvent, violate, or enable the circumvention or violation of, any
 * terms of an Apple operating system software license agreement.
 * 
 * Please obtain a copy of the License at
 * http://www.opensource.apple.com/apsl/ and read it before using this file.
 * 
 * The Original Code and all software distributed under the License are
 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
 * Please see the License for the specific language governing rights and
 * limitations under the License.
 * 
 * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
 */
/*
 * @OSF_COPYRIGHT@
 */
/* 
 * Mach Operating System
 * Copyright (c) 1991,1990,1989,1988,1987 Carnegie Mellon University
 * All Rights Reserved.
 * 
 * Permission to use, copy, modify and distribute this software and its
 * documentation is hereby granted, provided that both the copyright
 * notice and this permission notice appear in all copies of the
 * software, derivative works or modified versions, and any portions
 * thereof, and that both notices appear in supporting documentation.
 * 
 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
 * CONDITION.  CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
 * ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
 * 
 * Carnegie Mellon requests users of this software to return to
 * 
 *  Software Distribution Coordinator  or  Software.Distribution@CS.CMU.EDU
 *  School of Computer Science
 *  Carnegie Mellon University
 *  Pittsburgh PA 15213-3890
 * 
 * any improvements or extensions that they make and grant Carnegie Mellon
 * the rights to redistribute these changes.
 */
/*
 */

/*
 *	File:	vm/vm_map.h
 *	Author:	Avadis Tevanian, Jr., Michael Wayne Young
 *	Date:	1985
 *
 *	Virtual memory map module definitions.
 *
 * Contributors:
 *	avie, dlb, mwyoung
 */

#ifndef	_VM_VM_MAP_H_
#define _VM_VM_MAP_H_

#include <mach/mach_types.h>
#include <mach/kern_return.h>
#include <mach/boolean.h>
#include <mach/vm_types.h>
#include <mach/vm_prot.h>
#include <mach/vm_inherit.h>
#include <mach/vm_behavior.h>
#include <mach/vm_param.h>
#include <vm/pmap.h>

#ifdef	KERNEL_PRIVATE

#include <sys/cdefs.h>

__BEGIN_DECLS

extern void	vm_map_reference(vm_map_t	map);
extern vm_map_t current_map(void);

/* Setup reserved areas in a new VM map */
extern kern_return_t	vm_map_exec(
	vm_map_t		new_map,
	task_t			task,
	boolean_t		is64bit,
	void			*fsroot,
	cpu_type_t		cpu,
	cpu_subtype_t		cpu_subtype);

__END_DECLS

#ifdef	MACH_KERNEL_PRIVATE

#include <task_swapper.h>
#include <mach_assert.h>

#include <vm/vm_object.h>
#include <vm/vm_page.h>
#include <kern/locks.h>
#include <kern/zalloc.h>
#include <kern/macro_help.h>

#include <kern/thread.h>

#define current_map_fast()	(current_thread()->map)
#define	current_map()		(current_map_fast())

#include <vm/vm_map_store.h>


/*
 *	Types defined:
 *
 *	vm_map_t		the high-level address map data structure.
 *	vm_map_entry_t		an entry in an address map.
 *	vm_map_version_t	a timestamp of a map, for use with vm_map_lookup
 *	vm_map_copy_t		represents memory copied from an address map,
 *				 used for inter-map copy operations
 */
typedef struct vm_map_entry	*vm_map_entry_t;
#define VM_MAP_ENTRY_NULL	((vm_map_entry_t) 0)


/*
 *	Type:		vm_map_object_t [internal use only]
 *
 *	Description:
 *		The target of an address mapping, either a virtual
 *		memory object or a sub map (of the kernel map).
 */
typedef union vm_map_object {
	vm_object_t		vmo_object;	/* object object */
	vm_map_t		vmo_submap;	/* belongs to another map */
} vm_map_object_t;

#define named_entry_lock_init(object)	lck_mtx_init(&(object)->Lock, &vm_object_lck_grp, &vm_object_lck_attr)
#define named_entry_lock_destroy(object)	lck_mtx_destroy(&(object)->Lock, &vm_object_lck_grp)
#define named_entry_lock(object)		lck_mtx_lock(&(object)->Lock)
#define named_entry_unlock(object)		lck_mtx_unlock(&(object)->Lock)   
#if VM_NAMED_ENTRY_LIST
extern queue_head_t vm_named_entry_list;
#endif /* VM_NAMED_ENTRY_LIST */

/*
 *	Type:		vm_named_entry_t [internal use only]
 *
 *	Description:
 *		Description of a mapping to a memory cache object.
 *
 *	Implementation:
 *		While the handle to this object is used as a means to map
 * 		and pass around the right to map regions backed by pagers
 *		of all sorts, the named_entry itself is only manipulated
 *		by the kernel.  Named entries hold information on the
 *		right to map a region of a cached object.  Namely,
 *		the target cache object, the beginning and ending of the
 *		region to be mapped, and the permissions, (read, write)
 *		with which it can be mapped.
 *
 */

struct vm_named_entry {
	decl_lck_mtx_data(,	Lock)		/* Synchronization */
	union {
		vm_object_t	object;		/* object I point to */
		vm_map_t	map;		/* map backing submap */
		vm_map_copy_t	copy;		/* a VM map copy */
	} backing;
	vm_object_offset_t	offset;		/* offset into object */
	vm_object_size_t	size;		/* size of region */
	vm_object_offset_t	data_offset;	/* offset to first byte of data */
	vm_prot_t		protection;	/* access permissions */
	int			ref_count;	/* Number of references */
	unsigned int				/* Is backing.xxx : */
	/* boolean_t */		internal:1,	/* ... an internal object */
	/* boolean_t */		is_sub_map:1,	/* ... a submap? */
	/* boolean_t */		is_copy:1;	/* ... a VM map copy */
#if VM_NAMED_ENTRY_LIST
	queue_chain_t		named_entry_list;
	int			named_entry_alias;
	mach_port_t		named_entry_port;
#define NAMED_ENTRY_BT_DEPTH 16
	void			*named_entry_bt[NAMED_ENTRY_BT_DEPTH];
#endif /* VM_NAMED_ENTRY_LIST */
};

/*
 *	Type:		vm_map_entry_t [internal use only]
 *
 *	Description:
 *		A single mapping within an address map.
 *
 *	Implementation:
 *		Address map entries consist of start and end addresses,
 *		a VM object (or sub map) and offset into that object,
 *		and user-exported inheritance and protection information.
 *		Control information for virtual copy operations is also
 *		stored in the address map entry.
 */

struct vm_map_links {
	struct vm_map_entry	*prev;		/* previous entry */
	struct vm_map_entry	*next;		/* next entry */
	vm_map_offset_t		start;		/* start address */
	vm_map_offset_t		end;		/* end address */
};

/*
 * IMPORTANT:
 * The "alias" field can be updated while holding the VM map lock
 * "shared".  It's OK as along as it's the only field that can be
 * updated without the VM map "exclusive" lock.
 */
#define VME_OBJECT(entry) ((entry)->vme_object.vmo_object)
#define VME_OBJECT_SET(entry, object)				\
	MACRO_BEGIN						\
	(entry)->vme_object.vmo_object = (object);		\
	MACRO_END
#define VME_SUBMAP(entry) ((entry)->vme_object.vmo_submap)
#define VME_SUBMAP_SET(entry, submap)				\
	MACRO_BEGIN						\
	(entry)->vme_object.vmo_submap = (submap);		\
	MACRO_END
#define VME_OFFSET(entry) ((entry)->vme_offset & ~PAGE_MASK)
#define VME_OFFSET_SET(entry, offset)		\
	MACRO_BEGIN				\
	int __alias;				\
	__alias = VME_ALIAS((entry));		\
	assert((offset & PAGE_MASK) == 0);	\
	(entry)->vme_offset = offset | __alias;	\
	MACRO_END
#define VME_OBJECT_SHADOW(entry, length)			\
	MACRO_BEGIN						\
	vm_object_t		__object;			\
	vm_object_offset_t	__offset;			\
	__object = VME_OBJECT((entry));				\
	__offset = VME_OFFSET((entry));				\
	vm_object_shadow(&__object, &__offset, (length));	\
	if (__object != VME_OBJECT((entry))) {			\
		VME_OBJECT_SET((entry), __object);		\
		(entry)->use_pmap = TRUE;			\
	}							\
	if (__offset != VME_OFFSET((entry))) {			\
		VME_OFFSET_SET((entry), __offset);		\
	}							\
	MACRO_END

#define VME_ALIAS_MASK (PAGE_MASK)
#define VME_ALIAS(entry) ((unsigned int)((entry)->vme_offset & VME_ALIAS_MASK))
#define VME_ALIAS_SET(entry, alias) \
	MACRO_BEGIN							\
	vm_map_offset_t __offset;					\
	__offset = VME_OFFSET((entry));					\
	(entry)->vme_offset = __offset | ((alias) & VME_ALIAS_MASK);	\
	MACRO_END

/*
 * FOOTPRINT ACCOUNTING:
 * The "memory footprint" is better described in the pmap layer.
 *
 * At the VM level, these 2 vm_map_entry_t fields are relevant:
 * iokit_mapped:
 *	For an "iokit_mapped" entry, we add the size of the entry to the
 *	footprint when the entry is entered into the map and we subtract that
 *	size when the entry is removed.  No other accounting should take place.
 *	"use_pmap" should be FALSE but is not taken into account.
 * use_pmap: (only when is_sub_map is FALSE)
 *	This indicates if we should ask the pmap layer to account for pages
 *	in this mapping.  If FALSE, we expect that another form of accounting
 *	is being used (e.g. "iokit_mapped" or the explicit accounting of
 *	non-volatile purgable memory).
 *
 * So the logic is mostly:
 * if entry->is_sub_map == TRUE
 *	anything in a submap does not count for the footprint
 * else if entry->iokit_mapped == TRUE
 *	footprint includes the entire virtual size of this entry
 * else if entry->use_pmap == FALSE
 *	tell pmap NOT to account for pages being pmap_enter()'d from this
 *	mapping (i.e. use "alternate accounting")
 * else
 *	pmap will account for pages being pmap_enter()'d from this mapping
 *	as it sees fit (only if anonymous, etc...)
 */

struct vm_map_entry {
	struct vm_map_links	links;		/* links to other entries */
#define vme_prev		links.prev
#define vme_next		links.next
#define vme_start		links.start
#define vme_end			links.end

	struct vm_map_store	store;
	union vm_map_object	vme_object;	/* object I point to */
	vm_object_offset_t	vme_offset;	/* offset into object */

	unsigned int
	/* boolean_t */	is_shared:1,	/* region is shared */
	/* boolean_t */	is_sub_map:1,	/* Is "object" a submap? */
	/* boolean_t */	in_transition:1, /* Entry being changed */
	/* boolean_t */	needs_wakeup:1,	/* Waiters on in_transition */
	/* vm_behavior_t */ behavior:2,	/* user paging behavior hint */
		/* behavior is not defined for submap type */
	/* boolean_t */	needs_copy:1,	/* object need to be copied? */

		/* Only in task maps: */
	/* vm_prot_t */	protection:3,	/* protection code */
	/* vm_prot_t */	max_protection:3, /* maximum protection */
	/* vm_inherit_t */ inheritance:2, /* inheritance */
	/* boolean_t */	use_pmap:1,	/*
					 * use_pmap is overloaded:
					 * if "is_sub_map":
					 * 	use a nested pmap?
					 * else (i.e. if object):
					 * 	use pmap accounting
					 * 	for footprint?
					 */
	/* boolean_t */	no_cache:1,	/* should new pages be cached? */
	/* boolean_t */	permanent:1,	/* mapping can not be removed */
	/* boolean_t */	superpage_size:1, /* use superpages of a certain size */
	/* boolean_t */	map_aligned:1,	/* align to map's page size */
	/* boolean_t */	zero_wired_pages:1, /* zero out the wired pages of
					     * this entry it is being deleted
					     * without unwiring them */
	/* boolean_t */	used_for_jit:1,
	/* boolean_t */ pmap_cs_associated:1, /* pmap_cs will validate */
	/* boolean_t */	from_reserved_zone:1, /* Allocated from
					       * kernel reserved zone	 */

	/* iokit accounting: use the virtual size rather than resident size: */
	/* boolean_t */ iokit_acct:1,
	/* boolean_t */ vme_resilient_codesign:1,
	/* boolean_t */ vme_resilient_media:1,
	/* boolean_t */ vme_atomic:1, /* entry cannot be split/coalesced */
		__unused:4;
;

	unsigned short		wired_count;	/* can be paged if = 0 */
	unsigned short		user_wired_count; /* for vm_wire */
#if	DEBUG
#define	MAP_ENTRY_CREATION_DEBUG (1)
#define MAP_ENTRY_INSERTION_DEBUG (1)
#endif	
#if	MAP_ENTRY_CREATION_DEBUG
	struct vm_map_header	*vme_creation_maphdr;
	uintptr_t		vme_creation_bt[16];
#endif
#if	MAP_ENTRY_INSERTION_DEBUG
	uintptr_t		vme_insertion_bt[16];
#endif
};

/*
 * Convenience macros for dealing with superpages
 * SUPERPAGE_NBASEPAGES is architecture dependent and defined in pmap.h
 */
#define SUPERPAGE_SIZE (PAGE_SIZE*SUPERPAGE_NBASEPAGES)
#define SUPERPAGE_MASK (-SUPERPAGE_SIZE)
#define SUPERPAGE_ROUND_DOWN(a) (a & SUPERPAGE_MASK)
#define SUPERPAGE_ROUND_UP(a) ((a + SUPERPAGE_SIZE-1) & SUPERPAGE_MASK)

/*
 * wired_counts are unsigned short.  This value is used to safeguard
 * against any mishaps due to runaway user programs.
 */
#define MAX_WIRE_COUNT		65535



/*
 *	Type:		struct vm_map_header
 *
 *	Description:
 *		Header for a vm_map and a vm_map_copy.
 */


struct vm_map_header {
	struct vm_map_links	links;		/* first, last, min, max */
	int			nentries;	/* Number of entries */
	boolean_t		entries_pageable;
						/* are map entries pageable? */
#ifdef VM_MAP_STORE_USE_RB
	struct rb_head	rb_head_store;
#endif
	int			page_shift;	/* page shift */
};

#define VM_MAP_HDR_PAGE_SHIFT(hdr) ((hdr)->page_shift)
#define VM_MAP_HDR_PAGE_SIZE(hdr) (1 << VM_MAP_HDR_PAGE_SHIFT((hdr)))
#define VM_MAP_HDR_PAGE_MASK(hdr) (VM_MAP_HDR_PAGE_SIZE((hdr)) - 1)

/*
 *	Type:		vm_map_t [exported; contents invisible]
 *
 *	Description:
 *		An address map -- a directory relating valid
 *		regions of a task's address space to the corresponding
 *		virtual memory objects.
 *
 *	Implementation:
 *		Maps are doubly-linked lists of map entries, sorted
 *		by address.  One hint is used to start
 *		searches again from the last successful search,
 *		insertion, or removal.  Another hint is used to
 *		quickly find free space.
 */
struct _vm_map {
	lck_rw_t		lock;		/* map lock */
	struct vm_map_header	hdr;		/* Map entry header */
#define min_offset		hdr.links.start	/* start of range */
#define max_offset		hdr.links.end	/* end of range */
	pmap_t			pmap;		/* Physical map */
	vm_map_size_t		size;		/* virtual size */
	vm_map_size_t		user_wire_limit;/* rlimit on user locked memory */
	vm_map_size_t		user_wire_size; /* current size of user locked memory in this map */
#if __x86_64__
	vm_map_offset_t		vmmap_high_start;
#endif /* __x86_64__ */

	union {
		/*
		 * If map->disable_vmentry_reuse == TRUE:
		 * the end address of the highest allocated vm_map_entry_t.
		 */
		vm_map_offset_t		vmu1_highest_entry_end;
		/*
		 * For a nested VM map:
		 * the lowest address in this nested VM map that we would
		 * expect to be unnested under normal operation (i.e. for
		 * regular copy-on-write on DATA section).
		 */
		vm_map_offset_t		vmu1_lowest_unnestable_start;
	} vmu1;
#define highest_entry_end	vmu1.vmu1_highest_entry_end
#define lowest_unnestable_start	vmu1.vmu1_lowest_unnestable_start
	decl_lck_mtx_data(,	s_lock)		/* Lock ref, res fields */
	lck_mtx_ext_t		s_lock_ext;
	vm_map_entry_t		hint;		/* hint for quick lookups */
	union {
		struct vm_map_links* vmmap_hole_hint;	/* hint for quick hole lookups */
		struct vm_map_corpse_footprint_header *vmmap_corpse_footprint;
	} vmmap_u_1;
#define hole_hint vmmap_u_1.vmmap_hole_hint
#define vmmap_corpse_footprint vmmap_u_1.vmmap_corpse_footprint
	union{
		vm_map_entry_t		_first_free;	/* First free space hint */
		struct vm_map_links*	_holes;		/* links all holes between entries */
	} f_s;						/* Union for free space data structures being used */

#define first_free		f_s._first_free
#define holes_list		f_s._holes

	int			map_refcnt;	/* Reference count */

#if	TASK_SWAPPER
	int			res_count;	/* Residence count (swap) */
	int			sw_state;	/* Swap state */
#endif	/* TASK_SWAPPER */

	unsigned int		
	/* boolean_t */		wait_for_space:1, /* Should callers wait for space? */
	/* boolean_t */		wiring_required:1, /* All memory wired? */
	/* boolean_t */		no_zero_fill:1, /*No zero fill absent pages */
	/* boolean_t */		mapped_in_other_pmaps:1, /*has this submap been mapped in maps that use a different pmap */
	/* boolean_t */		switch_protect:1, /*  Protect map from write faults while switched */
	/* boolean_t */		disable_vmentry_reuse:1, /*  All vm entries should keep using newer and higher addresses in the map */ 
	/* boolean_t */		map_disallow_data_exec:1, /* Disallow execution from data pages on exec-permissive architectures */
	/* boolean_t */		holelistenabled:1,
	/* boolean_t */		is_nested_map:1,
	/* boolean_t */		map_disallow_new_exec:1, /* Disallow new executable code */
 	/* boolean_t */		jit_entry_exists:1,
	/* boolean_t */		has_corpse_footprint:1,
	/* boolean_t */		warned_delete_gap:1,
	/* reserved */		pad:19;
	unsigned int		timestamp;	/* Version number */
};

#define CAST_TO_VM_MAP_ENTRY(x) ((struct vm_map_entry *)(uintptr_t)(x))
#define vm_map_to_entry(map) CAST_TO_VM_MAP_ENTRY(&(map)->hdr.links)
#define vm_map_first_entry(map)	((map)->hdr.links.next)
#define vm_map_last_entry(map)	((map)->hdr.links.prev)

#if	TASK_SWAPPER
/*
 * VM map swap states.  There are no transition states.
 */
#define MAP_SW_IN	 1	/* map is swapped in; residence count > 0 */
#define MAP_SW_OUT	 2	/* map is out (res_count == 0 */
#endif	/* TASK_SWAPPER */

/*
 *	Type:		vm_map_version_t [exported; contents invisible]
 *
 *	Description:
 *		Map versions may be used to quickly validate a previous
 *		lookup operation.
 *
 *	Usage note:
 *		Because they are bulky objects, map versions are usually
 *		passed by reference.
 *
 *	Implementation:
 *		Just a timestamp for the main map.
 */
typedef struct vm_map_version {
	unsigned int	main_timestamp;
} vm_map_version_t;

/*
 *	Type:		vm_map_copy_t [exported; contents invisible]
 *
 *	Description:
 *		A map copy object represents a region of virtual memory
 *		that has been copied from an address map but is still
 *		in transit.
 *
 *		A map copy object may only be used by a single thread
 *		at a time.
 *
 *	Implementation:
 * 		There are three formats for map copy objects.  
 *		The first is very similar to the main
 *		address map in structure, and as a result, some
 *		of the internal maintenance functions/macros can
 *		be used with either address maps or map copy objects.
 *
 *		The map copy object contains a header links
 *		entry onto which the other entries that represent
 *		the region are chained.
 *
 *		The second format is a single vm object.  This was used
 *		primarily in the pageout path - but is not currently used
 *		except for placeholder copy objects (see vm_map_copy_copy()).
 *
 *		The third format is a kernel buffer copy object - for data
 * 		small enough that physical copies were the most efficient
 *		method. This method uses a zero-sized array unioned with
 *		other format-specific data in the 'c_u' member. This unsized
 *		array overlaps the other elements and allows us to use this
 *		extra structure space for physical memory copies. On 64-bit
 *		systems this saves ~64 bytes per vm_map_copy.
 */

struct vm_map_copy {
	int			type;
#define VM_MAP_COPY_ENTRY_LIST		1
#define VM_MAP_COPY_OBJECT		2
#define VM_MAP_COPY_KERNEL_BUFFER	3
	vm_object_offset_t	offset;
	vm_map_size_t		size;
	union {
		struct vm_map_header    hdr;      /* ENTRY_LIST */
		vm_object_t             object;   /* OBJECT */
		uint8_t                 kdata[0]; /* KERNEL_BUFFER */
	} c_u;
};


#define cpy_hdr			c_u.hdr

#define cpy_object		c_u.object
#define cpy_kdata		c_u.kdata
#define cpy_kdata_hdr_sz	(offsetof(struct vm_map_copy, c_u.kdata))

#define VM_MAP_COPY_PAGE_SHIFT(copy) ((copy)->cpy_hdr.page_shift)
#define VM_MAP_COPY_PAGE_SIZE(copy) (1 << VM_MAP_COPY_PAGE_SHIFT((copy)))
#define VM_MAP_COPY_PAGE_MASK(copy) (VM_MAP_COPY_PAGE_SIZE((copy)) - 1)

/*
 *	Useful macros for entry list copy objects
 */

#define vm_map_copy_to_entry(copy) CAST_TO_VM_MAP_ENTRY(&(copy)->cpy_hdr.links)
#define vm_map_copy_first_entry(copy)		\
		((copy)->cpy_hdr.links.next)
#define vm_map_copy_last_entry(copy)		\
		((copy)->cpy_hdr.links.prev)

/*
 *	Macros:		vm_map_lock, etc. [internal use only]
 *	Description:
 *		Perform locking on the data portion of a map.
 *	When multiple maps are to be locked, order by map address.
 *	(See vm_map.c::vm_remap())
 */

#define vm_map_lock_init(map)						\
	((map)->timestamp = 0 ,						\
	lck_rw_init(&(map)->lock, &vm_map_lck_grp, &vm_map_lck_rw_attr))

#define vm_map_lock(map)		lck_rw_lock_exclusive(&(map)->lock)
#define vm_map_unlock(map)						\
		((map)->timestamp++ ,	lck_rw_done(&(map)->lock))
#define vm_map_lock_read(map)		lck_rw_lock_shared(&(map)->lock)
#define vm_map_unlock_read(map)		lck_rw_done(&(map)->lock)
#define vm_map_lock_write_to_read(map)					\
		((map)->timestamp++ ,	lck_rw_lock_exclusive_to_shared(&(map)->lock))
/* lock_read_to_write() returns FALSE on failure.  Macro evaluates to 
 * zero on success and non-zero value on failure.
 */
#define vm_map_lock_read_to_write(map)	(lck_rw_lock_shared_to_exclusive(&(map)->lock) != TRUE)

#define vm_map_try_lock(map)		lck_rw_try_lock_exclusive(&(map)->lock)
#define vm_map_try_lock_read(map)	lck_rw_try_lock_shared(&(map)->lock)

#if MACH_ASSERT || DEBUG
#define vm_map_lock_assert_held(map) \
	lck_rw_assert(&(map)->lock, LCK_RW_ASSERT_HELD)
#define vm_map_lock_assert_shared(map)	\
	lck_rw_assert(&(map)->lock, LCK_RW_ASSERT_SHARED)
#define vm_map_lock_assert_exclusive(map) \
	lck_rw_assert(&(map)->lock, LCK_RW_ASSERT_EXCLUSIVE)
#define vm_map_lock_assert_notheld(map) \
	lck_rw_assert(&(map)->lock, LCK_RW_ASSERT_NOTHELD)
#else  /* MACH_ASSERT || DEBUG */ 
#define vm_map_lock_assert_held(map)
#define vm_map_lock_assert_shared(map)
#define vm_map_lock_assert_exclusive(map)
#define vm_map_lock_assert_notheld(map)
#endif /* MACH_ASSERT || DEBUG */

/*
 *	Exported procedures that operate on vm_map_t.
 */

/* Initialize the module */
extern void		vm_map_init(void);

extern void		vm_kernel_reserved_entry_init(void);

/* Allocate a range in the specified virtual address map and
 * return the entry allocated for that range. */
extern kern_return_t vm_map_find_space(
				vm_map_t		map,
				vm_map_address_t	*address,	/* OUT */
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				vm_map_entry_t		*o_entry);	/* OUT */

extern void vm_map_clip_start(
	vm_map_t	map,
	vm_map_entry_t	entry,
	vm_map_offset_t	endaddr);
extern void vm_map_clip_end(
	vm_map_t	map,
	vm_map_entry_t	entry,
	vm_map_offset_t	endaddr);
extern boolean_t vm_map_entry_should_cow_for_true_share(
	vm_map_entry_t	entry);

/* Lookup map entry containing or the specified address in the given map */
extern boolean_t	vm_map_lookup_entry(
				vm_map_t		map,
				vm_map_address_t	address,
				vm_map_entry_t		*entry);	/* OUT */

extern void		vm_map_copy_remap(
	vm_map_t		map,
	vm_map_entry_t		where,
	vm_map_copy_t		copy,
	vm_map_offset_t		adjustment,
	vm_prot_t		cur_prot,
	vm_prot_t		max_prot,
	vm_inherit_t		inheritance);

/* Find the VM object, offset, and protection for a given virtual address
 * in the specified map, assuming a page fault of the	type specified. */
extern kern_return_t	vm_map_lookup_locked(
				vm_map_t		*var_map,	/* IN/OUT */
				vm_map_address_t	vaddr,
				vm_prot_t		fault_type,
				int			object_lock_type,
				vm_map_version_t 	*out_version,	/* OUT */
				vm_object_t		*object,	/* OUT */
				vm_object_offset_t 	*offset,	/* OUT */
				vm_prot_t		*out_prot,	/* OUT */
				boolean_t		*wired,		/* OUT */
				vm_object_fault_info_t	fault_info,	/* OUT */
				vm_map_t		*real_map);	/* OUT */

/* Verifies that the map has not changed since the given version. */
extern boolean_t	vm_map_verify(
				vm_map_t	 	map,
				vm_map_version_t 	*version);	/* REF */

extern vm_map_entry_t	vm_map_entry_insert(
				vm_map_t		map,
				vm_map_entry_t		insp_entry,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_object_t		object,
				vm_object_offset_t	offset,
				boolean_t		needs_copy,
				boolean_t		is_shared,
				boolean_t		in_transition,
				vm_prot_t		cur_protection,
				vm_prot_t		max_protection,
				vm_behavior_t		behavior,
				vm_inherit_t		inheritance,
				unsigned		wired_count,
				boolean_t		no_cache,
				boolean_t		permanent,
				unsigned int		superpage_size,
				boolean_t		clear_map_aligned,
				boolean_t		is_submap,
				boolean_t		used_for_jit,
				int			alias);


/*
 *	Functions implemented as macros
 */
#define		vm_map_min(map)	((map)->min_offset)
						/* Lowest valid address in
						 * a map */

#define		vm_map_max(map)	((map)->max_offset)
						/* Highest valid address */

#define		vm_map_pmap(map)	((map)->pmap)
						/* Physical map associated
						 * with this address map */

/*
 * Macros/functions for map residence counts and swapin/out of vm maps
 */
#if	TASK_SWAPPER

#if	MACH_ASSERT
/* Gain a reference to an existing map */
extern void		vm_map_reference(
				vm_map_t	map);
/* Lose a residence count */
extern void		vm_map_res_deallocate(
				vm_map_t	map);
/* Gain a residence count on a map */
extern void		vm_map_res_reference(
				vm_map_t	map);
/* Gain reference & residence counts to possibly swapped-out map */
extern void		vm_map_reference_swap(
				vm_map_t	map);

#else	/* MACH_ASSERT */

#define vm_map_reference(map)		\
MACRO_BEGIN					\
	vm_map_t Map = (map);		\
	if (Map) {				\
		lck_mtx_lock(&Map->s_lock);	\
		Map->res_count++;		\
		Map->map_refcnt++;		\
		lck_mtx_unlock(&Map->s_lock);	\
	}					\
MACRO_END

#define vm_map_res_reference(map)		\
MACRO_BEGIN					\
	vm_map_t Lmap = (map);		\
	if (Lmap->res_count == 0) {		\
		lck_mtx_unlock(&Lmap->s_lock);\
		vm_map_lock(Lmap);		\
		vm_map_swapin(Lmap);		\
		lck_mtx_lock(&Lmap->s_lock);	\
		++Lmap->res_count;		\
		vm_map_unlock(Lmap);		\
	} else					\
		++Lmap->res_count;		\
MACRO_END

#define vm_map_res_deallocate(map)		\
MACRO_BEGIN					\
	vm_map_t Map = (map);		\
	if (--Map->res_count == 0) {	\
		lck_mtx_unlock(&Map->s_lock);	\
		vm_map_lock(Map);		\
		vm_map_swapout(Map);		\
		vm_map_unlock(Map);		\
		lck_mtx_lock(&Map->s_lock);	\
	}					\
MACRO_END

#define vm_map_reference_swap(map)	\
MACRO_BEGIN				\
	vm_map_t Map = (map);		\
	lck_mtx_lock(&Map->s_lock);	\
	++Map->map_refcnt;		\
	vm_map_res_reference(Map);	\
	lck_mtx_unlock(&Map->s_lock);	\
MACRO_END
#endif 	/* MACH_ASSERT */

extern void		vm_map_swapin(
				vm_map_t	map);

extern void		vm_map_swapout(
				vm_map_t	map);

#else	/* TASK_SWAPPER */

#define vm_map_reference(map)			\
MACRO_BEGIN					\
	vm_map_t Map = (map);			\
	if (Map) {				\
		lck_mtx_lock(&Map->s_lock);	\
		Map->map_refcnt++;		\
		lck_mtx_unlock(&Map->s_lock);	\
	}					\
MACRO_END

#define vm_map_reference_swap(map)	vm_map_reference(map)
#define vm_map_res_reference(map)
#define vm_map_res_deallocate(map)

#endif	/* TASK_SWAPPER */

/*
 *	Submap object.  Must be used to create memory to be put
 *	in a submap by vm_map_submap.
 */
extern vm_object_t	vm_submap_object;

/*
 *	Wait and wakeup macros for in_transition map entries.
 */
#define vm_map_entry_wait(map, interruptible)    	\
	((map)->timestamp++ ,				\
	 lck_rw_sleep(&(map)->lock, LCK_SLEEP_EXCLUSIVE|LCK_SLEEP_PROMOTED_PRI, \
				  (event_t)&(map)->hdr,	interruptible))


#define vm_map_entry_wakeup(map)        \
	thread_wakeup((event_t)(&(map)->hdr))


#define	vm_map_ref_fast(map)			\
	MACRO_BEGIN					\
	lck_mtx_lock(&map->s_lock);			\
	map->ref_count++;				\
	vm_map_res_reference(map);			\
	lck_mtx_unlock(&map->s_lock);			\
	MACRO_END

#define	vm_map_dealloc_fast(map)		\
	MACRO_BEGIN					\
	int c;						\
							\
	lck_mtx_lock(&map->s_lock);			\
	c = --map->ref_count;			\
	if (c > 0)					\
		vm_map_res_deallocate(map);		\
	lck_mtx_unlock(&map->s_lock);			\
	if (c == 0)					\
		vm_map_destroy(map);			\
	MACRO_END


/* simplify map entries */
extern void		vm_map_simplify_entry(
	vm_map_t	map,
	vm_map_entry_t	this_entry);
extern void		vm_map_simplify(
				vm_map_t		map,
				vm_map_offset_t		start);

/* Move the information in a map copy object to a new map copy object */
extern vm_map_copy_t	vm_map_copy_copy(
				vm_map_copy_t           copy);

/* Create a copy object from an object. */
extern kern_return_t	vm_map_copyin_object(
				vm_object_t		object,
				vm_object_offset_t	offset,
				vm_object_size_t	size,
				vm_map_copy_t		*copy_result); /* OUT */

extern kern_return_t	vm_map_random_address_for_size(
				vm_map_t	map,
				vm_map_offset_t	*address,
				vm_map_size_t	size);

/* Enter a mapping */
extern kern_return_t	vm_map_enter(
				vm_map_t		map,
				vm_map_offset_t		*address,
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				vm_object_t		object,
				vm_object_offset_t	offset,
				boolean_t		needs_copy,
				vm_prot_t		cur_protection,
				vm_prot_t		max_protection,
				vm_inherit_t		inheritance);

#if __arm64__
extern kern_return_t	vm_map_enter_fourk(
				vm_map_t		map,
				vm_map_offset_t		*address,
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				vm_object_t		object,
				vm_object_offset_t	offset,
				boolean_t		needs_copy,
				vm_prot_t		cur_protection,
				vm_prot_t		max_protection,
				vm_inherit_t		inheritance);
#endif /* __arm64__ */

/* XXX should go away - replaced with regular enter of contig object */
extern  kern_return_t	vm_map_enter_cpm(
				vm_map_t		map,
				vm_map_address_t	*addr,
				vm_map_size_t		size,
				int			flags);

extern kern_return_t vm_map_remap(
				vm_map_t		target_map,
				vm_map_offset_t		*address,
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				vm_map_t		src_map,
				vm_map_offset_t		memory_address,
				boolean_t		copy,
				vm_prot_t		*cur_protection,
				vm_prot_t		*max_protection,
				vm_inherit_t		inheritance);


/*
 * Read and write from a kernel buffer to a specified map.
 */
extern	kern_return_t	vm_map_write_user(
				vm_map_t		map,
				void			*src_p,
				vm_map_offset_t		dst_addr,
				vm_size_t		size);

extern	kern_return_t	vm_map_read_user(
				vm_map_t		map,
				vm_map_offset_t		src_addr,
				void			*dst_p,
				vm_size_t		size);

/* Create a new task map using an existing task map as a template. */
extern vm_map_t		vm_map_fork(
				ledger_t		ledger,
				vm_map_t		old_map,
				int			options);
#define VM_MAP_FORK_SHARE_IF_INHERIT_NONE	0x00000001
#define VM_MAP_FORK_PRESERVE_PURGEABLE		0x00000002
#define VM_MAP_FORK_CORPSE_FOOTPRINT		0x00000004

/* Change inheritance */
extern kern_return_t	vm_map_inherit(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_inherit_t		new_inheritance);

/* Add or remove machine-dependent attributes from map regions */
extern kern_return_t	vm_map_machine_attribute(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_machine_attribute_t	attribute,
				vm_machine_attribute_val_t* value); /* IN/OUT */

extern kern_return_t	vm_map_msync(
				vm_map_t		map,
				vm_map_address_t	address,
				vm_map_size_t		size,
				vm_sync_t		sync_flags);

/* Set paging behavior */
extern kern_return_t	vm_map_behavior_set(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_behavior_t		new_behavior);

extern kern_return_t vm_map_region(
				vm_map_t		 map,
				vm_map_offset_t		*address,
				vm_map_size_t		*size,
				vm_region_flavor_t	 flavor,
				vm_region_info_t	 info,
				mach_msg_type_number_t	*count,
				mach_port_t		*object_name);

extern kern_return_t vm_map_region_recurse_64(
				vm_map_t		 map,
				vm_map_offset_t		*address,
				vm_map_size_t		*size,
				natural_t	 	*nesting_depth,
				vm_region_submap_info_64_t info,
				mach_msg_type_number_t  *count);

extern kern_return_t vm_map_page_query_internal(
				vm_map_t		map,
				vm_map_offset_t		offset,
				int			*disposition,
				int			*ref_count);

extern kern_return_t vm_map_query_volatile(
	vm_map_t	map,
	mach_vm_size_t	*volatile_virtual_size_p,
	mach_vm_size_t	*volatile_resident_size_p,
	mach_vm_size_t	*volatile_compressed_size_p,
	mach_vm_size_t	*volatile_pmap_size_p,
	mach_vm_size_t	*volatile_compressed_pmap_size_p);

extern kern_return_t	vm_map_submap(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_map_t		submap,
				vm_map_offset_t		offset,
				boolean_t		use_pmap);

extern void vm_map_submap_pmap_clean(
	vm_map_t	map,
	vm_map_offset_t	start,
	vm_map_offset_t	end,
	vm_map_t	sub_map,
	vm_map_offset_t	offset);

/* Convert from a map entry port to a map */
extern vm_map_t convert_port_entry_to_map(
	ipc_port_t	port);

/* Convert from a port to a vm_object */
extern vm_object_t convert_port_entry_to_object(
	ipc_port_t	port);


extern kern_return_t vm_map_set_cache_attr(
        vm_map_t        map,
        vm_map_offset_t va);


/* definitions related to overriding the NX behavior */

#define VM_ABI_32	0x1
#define VM_ABI_64	0x2

extern int override_nx(vm_map_t map, uint32_t user_tag);

#if PMAP_CS
extern kern_return_t vm_map_entry_cs_associate(
	vm_map_t		map,
	vm_map_entry_t		entry,
	vm_map_kernel_flags_t	vmk_flags);
#endif /* PMAP_CS */

extern void vm_map_region_top_walk(
        vm_map_entry_t entry,
	vm_region_top_info_t top);
extern void vm_map_region_walk(
	vm_map_t map,
	vm_map_offset_t va,
	vm_map_entry_t entry,
	vm_object_offset_t offset,
	vm_object_size_t range,
	vm_region_extended_info_t extended,
	boolean_t look_for_pages,
	mach_msg_type_number_t count);


struct vm_map_corpse_footprint_header {
	vm_size_t	cf_size;	/* allocated buffer size */
	uint32_t	cf_last_region;	/* offset of last region in buffer */
	union {
		uint32_t cfu_last_zeroes; /* during creation:
					  * number of "zero" dispositions at
					  * end of last region */
		uint32_t cfu_hint_region; /* during lookup:
					  * offset of last looked up region */
#define cf_last_zeroes cfu.cfu_last_zeroes
#define cf_hint_region cfu.cfu_hint_region
	} cfu;
};
struct vm_map_corpse_footprint_region {
	vm_map_offset_t	cfr_vaddr;	/* region start virtual address */
	uint32_t	cfr_num_pages;	/* number of pages in this "region" */
	unsigned char	cfr_disposition[0];	/* disposition of each page */
} __attribute__((packed));

extern kern_return_t vm_map_corpse_footprint_collect(
	vm_map_t	old_map,
	vm_map_entry_t	old_entry,
	vm_map_t	new_map);
extern void vm_map_corpse_footprint_collect_done(
	vm_map_t	new_map);

extern kern_return_t vm_map_corpse_footprint_query_page_info(
	vm_map_t	map,
	vm_map_offset_t	va,
	int		*disp);

extern void vm_map_copy_footprint_ledgers(
	task_t	old_task,
	task_t	new_task);
extern void vm_map_copy_ledger(
	task_t	old_task,
	task_t	new_task,
	int	ledger_entry);

#endif /* MACH_KERNEL_PRIVATE */

__BEGIN_DECLS

/* Create an empty map */
extern vm_map_t		vm_map_create(
				pmap_t			pmap,
				vm_map_offset_t 	min_off,
				vm_map_offset_t 	max_off,
				boolean_t		pageable);
extern vm_map_t vm_map_create_options(
	pmap_t			pmap,
	vm_map_offset_t 	min_off,
	vm_map_offset_t 	max_off,
	int			options);
#define VM_MAP_CREATE_PAGEABLE		0x00000001
#define VM_MAP_CREATE_CORPSE_FOOTPRINT	0x00000002
#define VM_MAP_CREATE_ALL_OPTIONS (VM_MAP_CREATE_PAGEABLE | \
				   VM_MAP_CREATE_CORPSE_FOOTPRINT)

extern void		vm_map_disable_hole_optimization(vm_map_t map);

/* Get rid of a map */
extern void		vm_map_destroy(
				vm_map_t		map,
				int			flags);

/* Lose a reference */
extern void		vm_map_deallocate(
				vm_map_t		map);

extern vm_map_t		vm_map_switch(
				vm_map_t		map);

/* Change protection */
extern kern_return_t	vm_map_protect(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_prot_t		new_prot,
				boolean_t		set_max);

/* Check protection */
extern boolean_t vm_map_check_protection(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_prot_t		protection);

/* wire down a region */

#ifdef XNU_KERNEL_PRIVATE

extern kern_return_t	vm_map_wire_kernel(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_prot_t		access_type,
				vm_tag_t		tag,
				boolean_t		user_wire);

extern kern_return_t	vm_map_wire_and_extract_kernel(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_prot_t		access_type,
				vm_tag_t		tag,
				boolean_t		user_wire,
				ppnum_t			*physpage_p);

/* kext exported versions */

extern kern_return_t	vm_map_wire_external(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_prot_t		access_type,
				boolean_t		user_wire);

extern kern_return_t	vm_map_wire_and_extract_external(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_prot_t		access_type,
				boolean_t		user_wire,
				ppnum_t			*physpage_p);

#else /* XNU_KERNEL_PRIVATE */

extern kern_return_t	vm_map_wire(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				vm_prot_t		access_type,
				boolean_t		user_wire);

extern kern_return_t	vm_map_wire_and_extract(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_prot_t		access_type,
				boolean_t		user_wire,
				ppnum_t			*physpage_p);

#endif /* !XNU_KERNEL_PRIVATE */

/* unwire a region */
extern kern_return_t	vm_map_unwire(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				boolean_t		user_wire);

#ifdef XNU_KERNEL_PRIVATE

/* Enter a mapping of a memory object */
extern kern_return_t	vm_map_enter_mem_object(
				vm_map_t		map,
				vm_map_offset_t		*address,
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				ipc_port_t		port,
				vm_object_offset_t	offset,
				boolean_t		needs_copy,
				vm_prot_t		cur_protection,
				vm_prot_t		max_protection,
				vm_inherit_t		inheritance);

/* Enter a mapping of a memory object */
extern kern_return_t	vm_map_enter_mem_object_prefault(
				vm_map_t		map,
				vm_map_offset_t		*address,
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				ipc_port_t		port,
				vm_object_offset_t	offset,
				vm_prot_t		cur_protection,
				vm_prot_t		max_protection,
				upl_page_list_ptr_t	page_list,
				unsigned int 		page_list_count);

/* Enter a mapping of a memory object */
extern kern_return_t	vm_map_enter_mem_object_control(
				vm_map_t		map,
				vm_map_offset_t		*address,
				vm_map_size_t		size,
				vm_map_offset_t		mask,
				int			flags,
				vm_map_kernel_flags_t	vmk_flags,
				vm_tag_t		tag,
				memory_object_control_t	control,
				vm_object_offset_t	offset,
				boolean_t		needs_copy,
				vm_prot_t		cur_protection,
				vm_prot_t		max_protection,
				vm_inherit_t		inheritance);

#endif /* !XNU_KERNEL_PRIVATE */

/* Deallocate a region */
extern kern_return_t	vm_map_remove(
				vm_map_t		map,
				vm_map_offset_t		start,
				vm_map_offset_t		end,
				boolean_t		flags);

/* Deallocate a region when the map is already locked */
extern kern_return_t 	vm_map_remove_locked(
				vm_map_t        map,
				vm_map_offset_t     start,
				vm_map_offset_t     end,
				boolean_t       flags);

/* Discard a copy without using it */
extern void		vm_map_copy_discard(
				vm_map_copy_t		copy);

/* Overwrite existing memory with a copy */
extern kern_return_t	vm_map_copy_overwrite(
				vm_map_t                dst_map,
				vm_map_address_t        dst_addr,
				vm_map_copy_t           copy,
				boolean_t               interruptible);

/* returns TRUE if size of vm_map_copy == size parameter FALSE otherwise */
extern boolean_t	vm_map_copy_validate_size(
				vm_map_t		dst_map,
				vm_map_copy_t		copy,
				vm_map_size_t		*size);

/* Place a copy into a map */
extern kern_return_t	vm_map_copyout(
				vm_map_t		dst_map,
				vm_map_address_t	*dst_addr,	/* OUT */
				vm_map_copy_t		copy);

extern kern_return_t vm_map_copyout_size(
				vm_map_t		dst_map,
				vm_map_address_t	*dst_addr,	/* OUT */
				vm_map_copy_t		copy,
				vm_map_size_t		copy_size);

extern kern_return_t	vm_map_copyout_internal(
	vm_map_t		dst_map,
	vm_map_address_t	*dst_addr,	/* OUT */
	vm_map_copy_t		copy,
	vm_map_size_t		copy_size,
	boolean_t		consume_on_success,
	vm_prot_t		cur_protection,
	vm_prot_t		max_protection,
	vm_inherit_t		inheritance);

extern kern_return_t	vm_map_copyin(
				vm_map_t			src_map,
				vm_map_address_t	src_addr,
				vm_map_size_t		len,
				boolean_t			src_destroy,
				vm_map_copy_t		*copy_result);	/* OUT */

extern kern_return_t	vm_map_copyin_common(
				vm_map_t		src_map,
				vm_map_address_t	src_addr,
				vm_map_size_t		len,
				boolean_t		src_destroy,
				boolean_t		src_volatile,
				vm_map_copy_t		*copy_result,	/* OUT */
				boolean_t		use_maxprot);

#define VM_MAP_COPYIN_SRC_DESTROY	0x00000001
#define VM_MAP_COPYIN_USE_MAXPROT	0x00000002
#define VM_MAP_COPYIN_ENTRY_LIST	0x00000004
#define VM_MAP_COPYIN_PRESERVE_PURGEABLE 0x00000008
#define VM_MAP_COPYIN_ALL_FLAGS		0x0000000F
extern kern_return_t	vm_map_copyin_internal(
				vm_map_t		src_map,
				vm_map_address_t	src_addr,
				vm_map_size_t		len,
				int			flags,
				vm_map_copy_t		*copy_result); /* OUT */

extern kern_return_t	vm_map_copy_extract(
	vm_map_t		src_map,
	vm_map_address_t	src_addr,
	vm_map_size_t		len,
	vm_map_copy_t		*copy_result,	/* OUT */
	vm_prot_t		*cur_prot,	/* OUT */
	vm_prot_t		*max_prot);


extern void		vm_map_disable_NX(
			        vm_map_t		map);

extern void		vm_map_disallow_data_exec(
			        vm_map_t		map);

extern void		vm_map_set_64bit(
			        vm_map_t		map);

extern void		vm_map_set_32bit(
			        vm_map_t		map);

extern void		vm_map_set_jumbo(
			        vm_map_t		map);

extern void		vm_map_set_max_addr(
			        vm_map_t		map, vm_map_offset_t new_max_offset);

extern boolean_t	vm_map_has_hard_pagezero(
		       		vm_map_t		map,
				vm_map_offset_t		pagezero_size);
extern void		vm_commit_pagezero_status(vm_map_t	tmap);

#ifdef __arm__
static inline boolean_t vm_map_is_64bit(__unused vm_map_t map) { return 0; }
#else
extern boolean_t	vm_map_is_64bit(
			        vm_map_t		map);
#endif


extern kern_return_t	vm_map_raise_max_offset(
	vm_map_t	map,
	vm_map_offset_t	new_max_offset);

extern kern_return_t	vm_map_raise_min_offset(
	vm_map_t	map,
	vm_map_offset_t	new_min_offset);
#if __x86_64__
extern void vm_map_set_high_start(
	vm_map_t	map,
	vm_map_offset_t	high_start);
#endif /* __x86_64__ */

extern vm_map_offset_t	vm_compute_max_offset(
				boolean_t		is64);

extern void		vm_map_get_max_aslr_slide_section(
				vm_map_t		map,
				int64_t			*max_sections,
				int64_t			*section_size);

extern uint64_t 	vm_map_get_max_aslr_slide_pages(
				vm_map_t map);

extern uint64_t 	vm_map_get_max_loader_aslr_slide_pages(
				vm_map_t map);

extern void		vm_map_set_user_wire_limit(
				vm_map_t		map,
				vm_size_t		limit);

extern void vm_map_switch_protect(
				vm_map_t		map,
				boolean_t		val);

extern void vm_map_iokit_mapped_region(
				vm_map_t		map,
				vm_size_t		bytes);

extern void vm_map_iokit_unmapped_region(
				vm_map_t		map,
				vm_size_t		bytes);


extern boolean_t first_free_is_valid(vm_map_t);

extern int 		vm_map_page_shift(
				vm_map_t 		map);

extern vm_map_offset_t	vm_map_page_mask(
				vm_map_t 		map);

extern int		vm_map_page_size(
				vm_map_t 		map);

extern vm_map_offset_t	vm_map_round_page_mask(
				vm_map_offset_t		offset,
				vm_map_offset_t		mask);

extern vm_map_offset_t	vm_map_trunc_page_mask(
				vm_map_offset_t		offset,
				vm_map_offset_t		mask);

extern boolean_t	vm_map_page_aligned(
				vm_map_offset_t		offset,
				vm_map_offset_t		mask);

#ifdef XNU_KERNEL_PRIVATE
extern kern_return_t vm_map_page_info(
	vm_map_t		map,
	vm_map_offset_t		offset,
	vm_page_info_flavor_t	flavor,
	vm_page_info_t		info,
	mach_msg_type_number_t	*count);
extern kern_return_t vm_map_page_range_info_internal(
	vm_map_t		map,
	vm_map_offset_t		start_offset,
	vm_map_offset_t		end_offset,
	vm_page_info_flavor_t	flavor,
	vm_page_info_t		info,
	mach_msg_type_number_t	*count);
#endif /* XNU_KERNEL_PRIVATE */


#ifdef	MACH_KERNEL_PRIVATE

/*
 *	Macros to invoke vm_map_copyin_common.  vm_map_copyin is the
 *	usual form; it handles a copyin based on the current protection
 *	(current protection == VM_PROT_NONE) is a failure.
 *	vm_map_copyin_maxprot handles a copyin based on maximum possible
 *	access.  The difference is that a region with no current access
 *	BUT possible maximum access is rejected by vm_map_copyin(), but
 *	returned by vm_map_copyin_maxprot.
 */
#define	vm_map_copyin(src_map, src_addr, len, src_destroy, copy_result) \
		vm_map_copyin_common(src_map, src_addr, len, src_destroy, \
					FALSE, copy_result, FALSE)

#define vm_map_copyin_maxprot(src_map, \
			      src_addr, len, src_destroy, copy_result) \
		vm_map_copyin_common(src_map, src_addr, len, src_destroy, \
					FALSE, copy_result, TRUE)


/*
 * Internal macros for rounding and truncation of vm_map offsets and sizes
 */
#define VM_MAP_ROUND_PAGE(x,pgmask) (((vm_map_offset_t)(x) + (pgmask)) & ~((signed)(pgmask)))
#define VM_MAP_TRUNC_PAGE(x,pgmask) ((vm_map_offset_t)(x) & ~((signed)(pgmask)))

/*
 * Macros for rounding and truncation of vm_map offsets and sizes
 */
#define VM_MAP_PAGE_SHIFT(map) ((map) ? (map)->hdr.page_shift : PAGE_SHIFT)
#define VM_MAP_PAGE_SIZE(map) (1 << VM_MAP_PAGE_SHIFT((map)))
#define VM_MAP_PAGE_MASK(map) (VM_MAP_PAGE_SIZE((map)) - 1)
#define VM_MAP_PAGE_ALIGNED(x,pgmask) (((x) & (pgmask)) == 0)

static inline void vm_prot_to_wimg(unsigned int prot, unsigned int *wimg)
{ 
	switch (prot) {
		case MAP_MEM_NOOP:		break;
		case MAP_MEM_IO:		*wimg = VM_WIMG_IO; break;
		case MAP_MEM_COPYBACK:		*wimg = VM_WIMG_USE_DEFAULT; break;
		case MAP_MEM_INNERWBACK:	*wimg = VM_WIMG_INNERWBACK; break;
		case MAP_MEM_POSTED:		*wimg = VM_WIMG_POSTED; break;
		case MAP_MEM_WTHRU:		*wimg = VM_WIMG_WTHRU; break;
		case MAP_MEM_WCOMB:		*wimg = VM_WIMG_WCOMB; break;
		default:
			panic("Unrecognized mapping type %u\n", prot);
	}
}

#endif /* MACH_KERNEL_PRIVATE */

#ifdef XNU_KERNEL_PRIVATE
extern kern_return_t vm_map_set_page_shift(vm_map_t map, int pageshift);
#endif /* XNU_KERNEL_PRIVATE */

#define vm_map_round_page(x,pgmask) (((vm_map_offset_t)(x) + (pgmask)) & ~((signed)(pgmask)))
#define vm_map_trunc_page(x,pgmask) ((vm_map_offset_t)(x) & ~((signed)(pgmask)))

/*
 * Flags for vm_map_remove() and vm_map_delete()
 */
#define	VM_MAP_REMOVE_NO_FLAGS 		0x0
#define	VM_MAP_REMOVE_KUNWIRE	  	0x1
#define	VM_MAP_REMOVE_INTERRUPTIBLE  	0x2
#define	VM_MAP_REMOVE_WAIT_FOR_KWIRE  	0x4
#define VM_MAP_REMOVE_SAVE_ENTRIES	0x8
#define VM_MAP_REMOVE_NO_PMAP_CLEANUP	0x10
#define VM_MAP_REMOVE_NO_MAP_ALIGN	0x20
#define VM_MAP_REMOVE_NO_UNNESTING	0x40
#define VM_MAP_REMOVE_IMMUTABLE		0x80
#define VM_MAP_REMOVE_GAPS_OK		0x100

/* Support for UPLs from vm_maps */

#ifdef XNU_KERNEL_PRIVATE

extern kern_return_t vm_map_get_upl(
				vm_map_t		target_map,
				vm_map_offset_t		map_offset,
				upl_size_t		*size,
				upl_t			*upl,
				upl_page_info_array_t	page_info,
				unsigned int		*page_infoCnt,
				upl_control_flags_t	*flags,
				vm_tag_t		tag,
				int			force_data_sync);

#endif /* XNU_KERNEL_PRIVATE */

extern void
vm_map_sizes(vm_map_t map,
		vm_map_size_t * psize,
		vm_map_size_t * pfree,
		vm_map_size_t * plargest_free);

#if CONFIG_DYNAMIC_CODE_SIGNING
extern kern_return_t vm_map_sign(vm_map_t map, 
				 vm_map_offset_t start, 
				 vm_map_offset_t end);
#endif

extern kern_return_t vm_map_partial_reap(
              	vm_map_t map,
		unsigned int *reclaimed_resident,
		unsigned int *reclaimed_compressed);


#if DEVELOPMENT || DEBUG

extern int vm_map_disconnect_page_mappings(
	        vm_map_t map,
		boolean_t);
#endif


#if CONFIG_FREEZE

extern kern_return_t vm_map_freeze(
             	vm_map_t     map,
             	unsigned int *purgeable_count,
             	unsigned int *wired_count,
             	unsigned int *clean_count,
             	unsigned int *dirty_count,
             	unsigned int dirty_budget,
                unsigned int *shared_count,
		int	     *freezer_error_code,
		boolean_t    eval_only);


#define FREEZER_ERROR_GENERIC			(-1)
#define FREEZER_ERROR_EXCESS_SHARED_MEMORY	(-2)
#define FREEZER_ERROR_LOW_PRIVATE_SHARED_RATIO	(-3)
#define FREEZER_ERROR_NO_COMPRESSOR_SPACE	(-4)
#define FREEZER_ERROR_NO_SWAP_SPACE		(-5)

#endif

__END_DECLS

/*
 * In some cases, we don't have a real VM object but still want to return a
 * unique ID (to avoid a memory region looking like shared memory), so build
 * a fake pointer based on the map's ledger and the index of the ledger being
 * reported.
 */
#define INFO_MAKE_FAKE_OBJECT_ID(map,ledger_id)	((uint32_t)(uintptr_t)VM_KERNEL_ADDRPERM((int*)((map)->pmap->ledger)+(ledger_id)))

#endif	/* KERNEL_PRIVATE */
 
#endif	/* _VM_VM_MAP_H_ */
